/* E04DG_T1W_F C++ Header Example Program.
*
* Copyright 2021 Numerical Algorithms Group.
* Mark 27.2, 2021.
*/
#include <dco.hpp>
#include <iostream>
#include <math.h>
#include <nag.h>
#include <nagad.h>
#include <nagx02.h>
#include <stdio.h>
using namespace std;
extern "C"
{
static void NAG_CALL objfun(void *& ad_handle,
Integer & mode,
const Integer & n,
const nagad_t1w_w_rtype x[],
nagad_t1w_w_rtype & objf,
nagad_t1w_w_rtype objgrd[],
const Integer & nstate,
Integer iuser[],
nagad_t1w_w_rtype ruser[]);
}
int main(void)
{
int exit_status = 0;
nagad_t1w_w_rtype objf;
cout << "E04DG_T1W_F C++ Header Example Program Results\n\n";
// Create AD configuration data object
Integer ifail = 0;
void * ad_handle = 0;
nag::ad::x10aa(ad_handle, ifail);
// Read problem parameters and register for differentiation
// Skip first line of data file
string mystr;
getline(cin, mystr);
Integer n;
cin >> n;
// AD routine fixed length array arguments
Integer iuser[1], iwsav[610];
nagad_t1w_w_rtype ruser[1], rwsav[475];
char cwsav[1];
logical lwsav[120];
const Charlen name_l = 6, cwsav_l = 1;
// AD routine variable length arrays
Integer * iwork = 0;
nagad_t1w_w_rtype *x = 0, *x_in = 0, *objgrd = 0, *work = 0;
double * dfdx = 0;
iwork = new Integer[n + 1];
x = new nagad_t1w_w_rtype[n];
dfdx = new double[n];
x_in = new nagad_t1w_w_rtype[n];
objgrd = new nagad_t1w_w_rtype[n];
work = new nagad_t1w_w_rtype[13 * n];
double xr;
for (int i = 0; i < n; i++)
{
cin >> xr;
x_in[i] = xr;
}
double inc = 1.0;
for (int i = 0; i < n; i++)
{
for (int j = 0; j < n; j++)
{
x[j] = x_in[j];
}
dco::derivative(x[i]) = inc;
// Initialize sav arrays
ifail = 0;
nag::ad::e04wb("E04DGA", cwsav, 1, lwsav, 120, iwsav, 610, rwsav, 475,
ifail);
// Solve the problem
Integer iter;
objf = 0.0;
ifail = 0;
nag::ad::e04dg(ad_handle, n, objfun, iter, objf, objgrd, x, iwork, work,
-1, iuser, -1, ruser, lwsav, iwsav, rwsav, ifail);
dfdx[i] = dco::derivative(objf);
}
// Primal results
cout.setf(ios::scientific, ios::floatfield);
cout.precision(3);
cout << "\n Objective value = ";
cout.width(12);
cout << dco::value(objf);
cout << "\n Solution point = ";
for (int i = 0; i < n; i++)
{
cout.width(12);
cout << dco::value(x[i]);
}
cout << "\n Estim gradient = ";
for (int i = 0; i < n; i++)
{
cout.width(12);
cout << dco::value(objgrd[i]);
}
cout << "\n\n Derivatives calculated: First order tangents\n";
cout << " Computational mode : algorithmic\n\n";
cout << " Derivatives:\n\n";
// Get derivatives of solution points
cout << " dobjf/dx : ";
for (int i = 0; i < n; i++)
{
cout.width(12);
cout << dfdx[i];
}
cout << endl;
// Remove computational data object
nag::ad::x10ab(ad_handle, ifail);
delete[] iwork;
delete[] x;
delete[] dfdx;
delete[] x_in;
delete[] objgrd;
delete[] work;
return exit_status;
}
static void NAG_CALL objfun(void *& ad_handle,
Integer & mode,
const Integer & n,
const nagad_t1w_w_rtype x[],
nagad_t1w_w_rtype & objf,
nagad_t1w_w_rtype objgrd[],
const Integer & nstate,
Integer iuser[],
nagad_t1w_w_rtype ruser[])
{
// dco/c++ used here to perform AD of objfun
nagad_t1w_w_rtype x1, x2, y1, y2, expx1;
x1 = x[0];
x2 = x[1];
expx1 = exp(x1);
y1 = 2.0 * x1;
y1 = y1 + x2;
y2 = x2 + 1.0;
x1 = y1 * y1;
x2 = y2 * y2;
x1 = x1 + x2;
objf = expx1 * x1;
if (mode == 2)
{
y2 = y1 + y2;
y2 = 2.0 * y2;
y1 = 4.0 * y1;
y1 = expx1 * y1;
objgrd[0] = y1 + objf;
objgrd[1] = expx1 * y2;
}
return;
}